Reeba Panesar

Potential Applications of Immobilized β-Galactosidase in Food Processing Industries

The enzyme β-galactosidase can be obtained from a wide variety of sources such as microorganisms, plants, and animals. The use of β-galactosidase for the hydrolysis of lactose in milk and whey is one of the promising enzymatic applications in food and dairy processing industries. The enzyme can be used in either soluble or immobilized forms but the soluble enzyme can be used only for batch processes and the immobilized form has the advantage of being used in batch wise as well as in continuous operation. Immobilization has been found to be convenient method to make enzyme thermostable and to prevent the loss of enzyme activity. This review has been focused on the different types of techniques used for the immobilization of β-galactosidase and its potential applications in food industry.

Biotechnological approaches for the production of prebiotics and their potential applications

Worldwide interest in prebiotics have been increasing extensively both as food ingredients and pharmacological supplements, since they have beneficial properties for human health. Prebiotics not only stimulate the growth of healthy bacteria such as bifidobacteria and lactobacilli in the gut but also increase the resistance towards pathogens. In addition to this, they also act as dietary fiber, an energy source for intestinal cells after converting to short-chain fatty acids, a stimulator of immune systems, sugar replacer etc. Moreover, due to heat resistant properties, they are able to maintain their intact form during the baking process and allow them to be incorporated into every day food products. Thus, they can be interesting and useful ingredients in the development of novel functional foods. This review provides comprehensive information about the different biotechnological techniques employed in the production of prebiotics and their potential applications in different areas.

Fructo-oligosaccharides: Production, Purification and Potential Applications

The nutritional and therapeutic benefits of prebiotics have attracted the keen interest of consumers and food processing industry for their use as food ingredients. Fructo-oligosaccharides (FOS), new alternative sweeteners, constitute 1-kestose, nystose, and 1-beta-fructofuranosyl nystose produced from sucrose by the action of fructosyltransferase from plants, bacteria, yeast, and fungi. FOS has low caloric values, non-cariogenic properties, and help gut absorption of ions, decrease levels of lipids and cholesterol and bifidus-stimulating functionality. The purified linear fructose oligomers are added to various food products like cookies, yoghurt, infant milk products, desserts, and beverages due to their potential health benefits. This review is focused on the various aspects of biotechnological production, purification and potential applications of fructo-oligosaccharides.

Vermouth: technology of production and quality characteristics.

The aperitif wine, known as vermouth, is primarily prepared by adding a mixture of herbs and spices or their extract to a base wine. As such, it could also be called aromatized liquor, or a fortified wine. Various plant parts, such as seeds, wood, leaves, bark, or roots in dry form can be used in flavoring. These additives may be infused, macerated, or distilled in a base white wine, or added at various stages of preparation. The final liquid is filtered, pasteurized, and fortified (by the addition of alcohol). Some vermouths are sweetened, whereas other are left unsweetened (dry vermouth). These tend to have a bitterish finish. The two versions differ in alcohol content as well. Vermouths are most commonly prepared from grape-based wines, but fruit-based wines made from mango, apple, plum, sand pear, and wild apricot may also be used. These possess distinct physicochemical and sensory qualities from standard vermouths. The review gives comprehensive information on the historical developments and technology of vermouth production, the various spices and herbs used in its production, and its quality characteristics. In addition, the chapter also discusses the commercial potential of nongrape fruits in vermouth production.

Standardization of Medium components and Process parameters for Biopigment Production using Rhodotorula glutinis

In the present investigation, studies were carried out to evaluate the effect of medium consitituents and process paramters to get maximum biopigment production using Rhodotorula glutinis MTCC 1151. Screening of different media components indicated that a medium containing glucose (6%, w/v), urea (0.05%) and magnesium sulphate (0.05%) displayed higher pigment production than others. The optimization of different process parameters indicated that maximum pigment production was observed at pH 6.0, temperature 30°C, after 72 hrs incubation period under submerged fermentation.

Biopigment produced by Monascus purpureus MTCC 369 in submerged and solid state fermentation: a comparative study

Purpose Biopigments, natural colors from microbiological origin are of great interest because of their potential advantages over synthetic colorants. Therefore, this paper aims to evaluate the best possible fermentative conditions for the maximum production of biopigment using solid state fermentation and submerged fermentation by Monascus purpureus MTCC 369. Design/methodology/approach The biopigment was produced using solid state fermentation and submerged with optimized substrate to achieve higher yield. The statistical analysis was carried out using a Microsoft Excel ® (Microsoft Corporation). Findings On comparative analysis, it was observed that solid state fermentation resulted significant accumulation of biopigment (9.0 CVU/g) on the 9th day in comparison to submerged fermentation (5.1 CVU/g) on the 15th day. Practical implications Results revealed that sweet potato peel powder and pea pods provides necessary nutrients required for mycelial growth, and biopigment production, therefore, can be used as potent substrate for biopigment production by Monascus purpureus MTCC 369. Extracted color can be used in confectionery, beverages and pharmaceutical industries. Originality/value This work focuses on utilisation of waste for production of pigment as alternative source to synthetic colorant, and few studies have been carried out using wastes, but no work has been carried out on sweet potato peel to the best of the authors’ knowledge.